A Compact Coplanar Broadband Rectangular Slot Antenna with E-Shaped Feeding Structure for GPR Applications

A COMPACT COPLANAR BROADBAND RECTANGU-LAR SLOT ANTENNA WITH E-SHAPED FEEDING STRUCTURE FOR GPR APPLICATIONS

F. Sagnard*

Universit´e Paris-Est, IFSTTAR, Department MACS, 58, Bd Lefebvre, 75732 Paris Cedex 15, France

Abstract—A coplanar rectangular slot antenna operating in the very wide frequency band from 0.27 to 3.1 GHz (bandwidth over 166%) has been designed for GPR applications. The antenna, which is supposed to be positioned on the soil surface, appears particularly compact (34×29 cm2_{) and exhibits a low cross-polarization in the E-plane.} 3D FDTD simulations have allowed to make a detailed parametric study associated with the antenna dimensional parameters in order to optimize the radiating performances. The slot antenna has also been studied with a shield to be further integrated in a bistatic subsurface radar positioned on the soil surface. Simulated results of the link in the presence of a homogeneous soil then including buried objects met in civil engineering structures are presented and discussed. First experimental results on a sandy soil have been compared to numerical ones.

1. INTRODUCTION

Antennas with broadband characteristics have recently found various applications in modern ultra wide band (UWB) communication systems and in ground penetrating radar (GPR) [1–8]. Our applications are focused on imaging the subsurface of a large range of civil engineering structures at several depths using a bistatic GPR positioned on or close to the ground surface [8–10]. The development of a compact broadband pair of antennas operating in all the frequency band from 0.27 to 3.1 GHz, whose radiation characteristics have been preliminarily studied theoretically in details in different configurations, allows the probing of the subsurface in several frequency sub-bands using a step frequency (SF-GPR) acquisition mode.

Received 29 September 2011, Accepted 4 April 2012, Scheduled 22 April 2012

Microstrip patch antennas (MPAs) are one of the most basic and important types of planar antennas because they offer many advantages such as compact size, low-cost, ease of fabrication, light weight, and various shapes design [2, 3]. However, a low bandwidth and a low gain are the main shortcomings for such a planar structure. The microstrip antenna has now reached maturity, and many techniques have been suggested for achieving a high bandwidth such as using more complex shapes, parasitic elements, multilayer configurations and the tuning of the feed line [11–14]. In this paper, an original printed rectangular slot antenna fed by a 50 Ω CPW (coplanar waveguide) transmission line tuned by a E-shaped patch is presented [13, 14]. Presently, little work has been done to lower the operating frequency band of microstrip antennas at frequencies less than 0.8 MHz and to reduce the antenna size at these frequencies because major applications concern UWB wireless communications. The main concern of this study is to rely on recent developments in coplanar technology associated with ultra wide band (UWB) or broad band antennas to design a compact (34×29 cm2_{) antenna operating at a frequency as low} as 0.27 GHz, thus quite lower than 1 GHz [2, 3]. By choosing a relative combination of a E-shaped patch, a linear feed line and a rectangular slot, we have designed an antenna structure on a FR4 substrate (h = 1.5 mm) with a very wide operating bandwidth whose nearly half of the spectrum covers frequencies lower than 1 GHz. A partial shield, only opened towards the ground and coated with an inner layered absorbing material, has been added to eliminate undesirable reflections from the upper environment particularly at low frequencies; moreover, in a GPR system, the antenna shielding will allow to reduce the coupling between the transmitting and the receiving units [9].

In this paper, the proposed broadband rectangular slot antenna has been simulated using the 3D commercial software EMPIRE (distributed by IMST) based on the finite difference time domain (FDTD) technique. A first detailed parameter study done in air has allowed to define the several geometrical parameters of the unshielded slot antenna, which are the result of a compromise on the frequency bandwidth (reflection coefficient S11 < −10 dB) and compact dimensions. Afterwards, the antenna radiation characteristics have been studied in the presence of a shield (conductive box coated with a multi-layered lossy material) and a common soil (ε0 _{= 5.5;σ =}

2. ANTENNA STRUCTURE AND DESIGN

2.1. Antenna Structure

The geometry of the proposed rectangular slot (L1 = 270 mm;W1 = 165 mm) antenna with all its parameters is shown in Figures 1(a) and 1(b). The antenna has been designed on a classical single-sided FR4 (ε0

r = 4.4; tanδ = 0.01) substrate, with thickness hs = 1.5 mm.

The patch size is characterized by a length Ws = 288.5 mm and a

width Ls = 340 mm. The rectangular slot is excited by a CPW

feed-line with a characteristic impedance 50 Ω whose length is l= 77 mm; the CPW transmission line itself is formed by a conductive strip with a widthb= 3 mm and a gap distancea= 0.4 mm between the strip and the coplanar ground plane. The two finite ground planes are placed symmetrically at both sides of the CPW line. The E-shaped tuning patch and its relative position in the rectangular aperture strongly influences the S₁₁ frequency variations. Moreover, the associated trident feed line has allowed to significantly increase the bandwidth beyond frequencies greater than 1 GHz. The trident feed line has a lower width than the CPW line with b0 _{= 2 mm. The 3D simulations}

of the antenna under the commercial software EMPIRE, based on the FDTD approach, have allowed to perform a detailed parametric study associated with the geometrical elements to obtain a return loss

S11< −10 dB in the frequency band of 0.27 to 3.1 GHz. The influence of main parameters such as W2;W4;L2;L3;L4;c and the trident feed line are reported. Afterwards, the far-field radiation patterns associated with fields Eθ and Eϕ corresponding to the co-polar and

cross-polar components in both planesE-plane (x-z) andH-plane (y

-z) are presented at several frequencies in air.

The radiation of the rectangular slot antenna (field modes), which is initially a narrow band antenna, has been described by the cavity model [3]. The fringing effect induced at the open side walls produces radiation along the antenna width W1; however in our case, we have verified that this effect appears negligible (0.53% for f10). The introduction of a tuning stub inside the slot has allowed to create a very broad impedance bandwidth. The resonant frequencyfmn of the

excited mode TMmn is obtained using the following relation [3]:

f_mn= c 2pε0

e "µ

m L1

¶₂

+

µ n W1

¶₂#1/2

(1)

whereε0

e is the effective real permittivity.

lower resonant frequencyf₁₀ = 265.6 MHz. The 3 following frequency modes (L/W = 1.64) are f₀₁ = 437 MHz, f₂₀ = 534.1 MHz and

f₂₁= 690.1 MHz.

The current distribution on the antenna surface has been calculated by numerical simulations; the results visualized in Figure 2 at the frequency 560 MHz highlight that the trident-shaped feed line provides the alignment of the surface current jxy in the patch along

the 0x axis in a quasi uniform distribution [14].

2.2. Parametric Study Associated with the Geometry

The influence of main geometrical parameters on the return lossS₁₁of the rectangular slot antenna in air are now detailed. This study allows to justify the final dimensions defined in Figure 1.

Firstly, the trident-shaped feed has been studied. As shown in Figure 3(a), the trident-shaped feed considerably increases the bandwidth (S11 < −10 dB) of the antenna to the upper frequency

Ws=288.5

W1=165. 2

conductor

L1=27 0

L6=94

W2=96

W3=9

W4=11.5

Ls=340 L3=16.6

L4=37 5 P1

W6=6

L2=82

L4=37. 5

W5=2. 5 P1

L5=5. 6

(a)

b’=2 _c=23 distances in mm

(b)

b=3

b’=2

l=77 P1 a=0.4

CPW-fed rectangular slot antenna

trident E-shaped feed line

560 MHz

jxy

Figure 2. Current distribution jxy of the surface of the rectangular

slot antenna at frequency 560 MHz (incident pulse current 0.2 A, and duration 0.52 ns).

10 10

-10 0

-10 0

-20 10

S11

[d

B]

-20 10

S11

[d

B]

1.1 GHz 265 MHz

3.15 GHz

-40 -30

c=23 mm c=22 mm c=24 mm -40

-30

W4=11. 5 mm W4=9.5 m m W4=13. 5 mm

(original )

577 MHz

(original )

0 1 2 3 4

-50

frequency [GHz]

L3=11 mm

0 1 2 3 4

-50

frequency [GHz]

1 feed line

(a) (b)

Figure 3. Return loss S11 (dB) of the rectangular slot antenna in air (a) for various W4 values and feed line structures, and (b) various c and L3 values.

the frequency bandwidth and the return loss amplitude. In Figure 3(b), the study of the influence distance c between each parallel feed lines ranging from 22 to 24 mm shows that it affects the S₁₁ amplitude and the upper bandwidth limit; thus, the value c = 23 mm has been fixed. The heightL3 of the upper element of the E-patch shows from Figure 3(b) that it influences the bandwidth at the higher frequencies and the S11 amplitude; consequently, the value L3 = 16.6 mm has been defined. Afterwards, the influence of the dimensions (L2;W2) of the E shaped patch has been studied. From Figure 4(a), we remark that in the range 76 to 88 mm, the height L2 influences the S11 amplitudes for frequencies higher than 0.85 GHz and also the upper bandwidth limit; we have defined the optimum value to 82 mm to obtainS11 amplitudes clearly less than−10 dB around 2.3 GHz. From Figure 4(b), we observe that parameterW2 influences significantlyS11 amplitudes at frequencies ranging from 0.29 to 2.4 GHz and slightly the upper bandwidth; the valueW₂ = 96 mm appears to be the optimum solution.

The radiation patterns associated with theE-field (co-polarisation and cross-polarisation), in both planes, E-plane (φ = 0◦_{; x0z) and} H-plane (φ = 90◦_{; yOz), and expressed in terms of the total gain}

(including ohmic and reflection losses|S11|2) are presented in Figure 5 for four frequencies 0.3, 1, 2, and 2.8 GHz. In theE-plane, we generally remark that there is quite low cross polarization between bothE-field components Eθ and Eϕ; the gain is evaluated to 3.25 dB at 0.3 GHz,

6 dB at 1 GHz, 2.4 dB at 2 GHz, and 1.31 dB at 2.8 GHz. A maximum gain is thus observed around 1 GHz, and the weak gain for this slot antenna is a priori due to the compact size of the antenna, its very

10 10

10 0

10 0

-20 -10

S11

[d

B]

-20 -10

S11

[d

B]

-40 -30

W2=96 mm W2=81 m m -40

-30

L2=82 mm L2=76 mm

(original ) original )

0 1 2 3 4

-50

frequency [GHz]

W2=81 m m W2=111 mm

0 1 2 3 4

-50

frequency [GHz]

L2=76 mm L2=88 mm

(

(a) (b)

-10 10

30 0 30 -10

10 30 0 30

Ethe ta,phi= 0° Ephi,phi=0° Ethe ta,phi= 90° Ephi,phi=90°

300 MHz 1 GHz

-50

-30 ₆₀

60

90 90

-50

-30 ₆₀

60

90 90

120 120

90 90

120 120

90 90

150 180

150 150

180 150

(a) 2 GHz

-30 -10 10

60 30 0 30

60

2.8 GHz

-30 -10 10

60 30 0 30

60

-50

90 90

-50

90 90

120

150 150

120 120

150 150

120

150 180

150 150

180 150

(c)

(b)

(d)

Figure 5. Far-field radiation patterns (Eθ andEϕ, losses included) in

air of the rectangular slot antenna without shield in theE-plane (xOz) and H-plane (yOz) at 0.3, 1, 2 and 2.8 GHz.

wide frequency band and the high permittivity of the substrate. The gain could be improved using several approaches synthesized in [15], and it will be the second objective of this work, as the first one was to show that a quite compact slot antenna operating at low frequencies can be designed using the microstrip technology. In theH -plane, we remark that the minimum cross-polarisation between both

E-field components is evaluated to 4.8 dB. At 2 GHz and higher, the amplitudes of bothE-field components appear very close, and at these frequencies electromagnetic waves will not penetrate a soil. At 1 GHz, the maximum gain obtained for the component Eϕ is evaluated to

2.3. Effect of a Partial Shield

When designing a radar system supposed to be positioned parallel to the ground surface, it appears necessary to eliminate the backward radiations in air induced by the environment, and to reduce significantly the direct coupling between the transmitting and the receiving antennas. According to previous studies [9, 16], a rectangular shield formed of a perfectly conductive box and coated by an inner flat absorbing material has been added. In general, the dielectric characteristics of commercial absorbers are not known for confidential reasons, and approximate models are made. A characterization in reflection is generally made to extract the reflection coefficient of each absorbing layer to extract the complex permittivity and the permeability as a function of the frequency. Our model is based on Atteia’s simple model [9] which has considered a conductivity profile to reduce sharp reflections at the cavity frontiers. We have previously used this model [16] and observed that S11 bandwidth remains unchanged as compared to the unshielded case, and also that theoretical and numerical results compare satisfactorily.

In this work, we have considered a flat absorbing material (called Radar Absorbing Material RAM) made of three layers with a low dielectric constantε1,2,3= 1.5. As visualized in Figure 6, the antenna shield has the following width length and height hc = 356.5 mm,

Lc = 432 mm, and hc = 76.5 mm (e1+e2+e3). The RAM shows an

Wc=356.5 mm

conductive box coated by a layered absorbing material

Lc=432 mm

e1=35 mm

e₂=27.5 mm

e =20 mm

e3=20 mm _{3 layered absorbing}

material

-10 0

-20

[d

B]

275 MHz 3.15 GHz

-30

S11

NS h i

0 1 2 3 4

-50

-40 NSh air

NSh soil Sh air Sh soil

0 1 2 3 4

frequency [GHz]

Figure 7. Return loss S11 (dB) of the rectangular slot antenna in air and in the presence of a common soil (ε0

s = 5.5; σs = 0.01 S·m−1,

elevation h= 10 mm) with or without a shield.

increasing conductivity profile from the antenna patch to upper part of the box such as: σ1 = 0.01 S·m−1; e1 = 35 mm; σ2 = 0.1 S·m−1;

e2 = 27.5 mm and σ3 = 1 S·m−1; e3 = 20 mm. We have shown that with this model a minimum box height of 76.5 mm is necessary to affect weakly the S₁₁ amplitude. Moreover, weak variations of the several layer thicknesses do not significantly modify the S₁₁ plot. All the antenna structure has been simulated under EMPIRE in two configurations: in the presence of air and of a half-space common soil (ε0

s = 5.5; σs = 0.01 S·m−1) at an elevation h = 10 mm (to

consider potential irregularities on the soil surface). TheS11amplitude variations presented in Figure 7 show that in air the shield does not bring modifications. However, in air the presence of a shield produces a S11 amplitude higher in the frequency range [0.37; 1.3] GHz. On top of a common soil (h = 10 mm), the shielded antenna appears more matched than in air as the S11 amplitude in the bandwidth appears lower than −15 dB. In general, we observe that the shield smoothes the return loss response and does not change the bandwidth. The associated impedance variations (real and imaginary parts) versus frequency and plotted in Figures 8(a) and 8(b) for a shielded antenna in air and a presence of a soil confirm that the soil contributes to smooth the variations; in the bandwidth, the real part varies between 26.7 and 89.3 Ω, and between 39.3 and 72.3 Ω.

100 150

100 150

0 50

1

1

[O

hm

s]

0 50

1

1

[O

hm

s]

-100 -50

Z

1

real p art (air ) imag part (air) real rt sh. (air)

-100 -50

Z

1

real par t sh . (a ir) imag part sh . (a ir) real par t sh . (soi l)

0 1 2 3 4

-150

frequency [GHz]

ea (a )

imag part sh . (air)

3.35 GHz

295 MHz 0 1 2 3 4

-150

frequency [GHz]

p (

imag part sh . (soil)

3.27 GHz

(a) (b)

pa

Figure 8. Complex impedance of the rectangular slot antenna shielded in air and in the presence of a common soil (ε0

s = 5.5;

σ_s = 0.01 S·m−1_{, elevation h = 10 mm), (a) real and (b) imaginary} parts.

3. RADAR SYSTEM

3.1. Homogeneous Soil

The radar system, modeled under EMPIRE and visualized in Figure 10(a), is made of a pair of transmitting (50 Ω) and receiving (10 kΩ) rectangular shielded slot antennas positioned parallel to a semi infinite common homogeneous soil (ε0

s = 5.5;σs= 0.01 S·m−1) in the

mirror configuration at an elevationh= 10 mm. Firstly, the influence of the distancedbetween both antennas on the transmission coefficient

-10 10

30 0 30

Ethet a, phi= 0° Ephi,phi=0° Ethet a, phi= 90°

Ephi,phi=90° -10

10 30 0 30

300 MHz 1 GHz

-50

-30 ₆₀

60

90 90

p ,p

-50

-30 ₆₀

60

90 90

120 120

90 90

120 120

90 90

150 180

150 150

180 150

-30 -10 10

60 30 0 30

60

2 GHz 2.8 GHz

-30 -10 10

60 30 0 30

60 -50

90 90

-50

90 90

120

150 150

120 120

150 150

120

150 180

150 150

180 150

(a) (b)

(c) (d)

Figure 9. Far-field radiation patterns (E_θ andE_ϕ, losses included) in air of the rectangular slot antenna shielded in theE-plane (xOz) and

H-plane (yOz) at 0.3, 1, 2 and 2.8 GHz.

average of the velocity in air (c) and in the soil (c/pε0

s) such as:

v_av = 1 2

à c+pc

ε0 s

!

(2)

Thus, the first arrival time (offset = 100 mm) is evaluated analytically to 3.47 ns which is confirmed by the numerical results collected in Figure 10(b).

4 6

8 _offset=60

offset=80 mm offset=100 mm ut1inc/2000

Incident pulse

2 0 2 4 tude [m V]

offset=120 mm offset=140 mm 1st arrival

transmitting antenna receiving PML air -6 -4 -2 am pl i superimposing f 2 offset antenn a s=703 mm+offset P1 P2

0 2 4 6 8 10 12

-10 -8

time [ns] 3.73

0.5 propagationin the soil of 2 waves

(10 k (50 soil PML PML h 70 -60 -50 offset=100 mm (a) -90 -80 -70 S 11 [d B] -110 -100 S

0 1 2 3 4

-120 frequency [GHz] (c) (b) 5 . 5 ' s s 1 . m S s ε = σ =0.01 − Ω )

Ω )

Figure 10. FDTD simulations in the parallel configuration. (a) Geometry of the radar system above a common soil (ε0

s = 5.5;

σs = 0.01 S·m−1) at an elevationh(all distances are in mm), (b) time

signal at Port 2 for different values of the offset, and (c) the associated transmission coefficientS21 (dB).

3.2. Soil with Buried Objects

Then, two types of objects, a dielectric (ε0

diel = 3.4 thickness 1 mm) pipe with a radius 100 mm and a vertical crack with width 52 mm, both filled with air have been buried in the common homogeneous soil (ε0

s = 5.5; σs = 0.01 S ·m−1) as shown in Figures 12(a) and 12(b)

40

soil only h=0 offset=100 mm

10 20 30

V]

soil only h 0

-20 -10 0

am

pl

it

ude

[

m

soil only h=10 mm

50 - 40 -30

soil only h=10 mm

0 2 4 6 8 10 12 14 50

time [ns]

-Figure 11. Time signal at Port 2 for two elevation distances h = 0 and 10 mm above the common soil (ε0_s = 5.5; σs = 0.01 S ·m−1,

offset = 100 mm).

P1

PML

displacement distance d

0 configuration mirror

120 5

. 5 '

s

P1

P2

PML PML

e=120 mm

e=120 mm 2r=100 mm

(a)

c1=280 mm s

1 . m S s

PML

PML soil

soil

f=52 mm (a)

(b)

c1=280 mm

transmission reception

(c) ε =

σ =0.01 −

5 5 ' s

1 . m S s ε = σ =0.01 −

.

e L

S=703 mm + offset

elevation h (h << 2L), we can consider the following relation to analyze the several time waveforms

2L = 2pe2_+s2_{/4 (3)}

t1 = 2L

vsoil; vsoil =

c p

ε0 s

(4)

Thus, the propagation time t1 is estimated to be 6.9 ns using the analytical relations (3) and (4) if we consider the distance between ports s = 743 mm (offset = 100 mm); in this configuration, if the distance between antenna centers is scenter = 494.5 mm, the propagation timet1is evaluated to be 5.62 ns, thus very close to 5.67 ns calculated from numerical simulations (see Figure 13(a)). Because the pipe depth appears small as compared to the antenna distance

s, we observe in Figure 13(a) an overlap of two wave components around 6 ns associated with the direct wave propagating in the soil and the reflected wave from the dielectric pipe. Both signals associated with the pipe and the crack appear similar. However the signal corresponding to the crack appears about twice weaker, and its width is twice weaker as the pipe diameter. It must be mentioned that the crack has a semi-infinite extent in depth. In general, we remark that the direct waves generated in the presence of a homogeneous soil show very low amplitudes as compared to the wave reflected by the buried object. The displacement of the radar system on the soil

0 30 2 4 2 4 6 itinc*20

10 20

V

] incident it1*20

crack depth 120 mm

pipe depth 120 mm

3 4 0 5 ns

propagation in the soil

4 6 8 tim e [n s] - 4 - 2 0 -10 0 amp lit ude [m V direct waves soil only

mm )

3.4 ns surface wav e 0.5 n s

8

10 - 8

- 6 i di -30 -20 object detected (offset=40 mm )

soil only (offset=100 mm)

5.67 ns

(a)

0 20 40 60 80 100 120 12

distance [mm]

10

pipe ra dius

0 2 4 6 8 10 12

-40

time [ns]

detected

(b)

-

Figure 13. Time signals at Port 2 issued from the buried objects in the common soil (ε0

s= 5.5;σs= 0.01 S·m−1). (a) Comparison of the

40

40 _{pipe depth}

120mm 2 n s

10 20 30

m

V]

10 20 30

m

V]

pipe depth 220 mm

120mm 2 n s _{dielectric pipe}

depth 120 mm

2 layers depth 120 mm

pipe

-20 -10 0

am

pl

it

ude

[

-20 -10 0

am

pl

it

ude

[

soil only

(offset=40 mm) soil only

h=10 mm

-50 -40 -30

-50 -40 -30

0

pipe

0 2 4 6 8 10 12 14

50

time [ns]

0 2 4 6 8 10 12 14

50

time [ns]

(a) (b)

Figure 14. Time signals at Port 2 issued from several configurations. (a) Several pipe depths 120 and 220 mm, and (b) a pipe at depth 120 mm and a two-layered soil (layer 1 e₁ = 120 mm, ε0

1 = 5.5;σ1 = 0.01 S·m−1_{, and layer 2 e}

2 → ∞, ε02 = 9; σ2 = 0.01 S·m−1) with an interface at the depth 120 mm.

surface at a fixed offset (offset = 100 mm) along the direction Ox

(B-scan) gives a radargram; considering the homogeneous soil with the buried pipe (offset = 100 mm, e = 120 mm, h = 10 mm), the radargram presented in Figure 13(b) shows part of the hyperbola (the shape of the incident signal has been plotted). Afterwards, the same pipe has been buried 100 mm deeper, thus 220 mm under the soil surface, and we have compared in Figure 14(a) the waveforms at both depths. Considering the distance between antenna centers

s_center = 494.5 mm, the propagation time t₁ is evaluated to be 7.9 ns; a marked peak can be visualized in Figure 14(a) close to the time 8 ns. The signal before corresponds to the reflection between the antenna shields. Afterwards, a double layered soil has been considered with the following characteristics associated with the thicknesses and the complex permittivities: layer 1, e1 = 120 mm, ε01 = 5.5; σ = 0.01 S·m−1, and layer 2 e2 → ∞, ε02 = 9;σ = 0.01 S·m−1. The time difference between successive signals reflected on the interface between both layers is theoretically 1.9 ns, which corresponds to the signals observed in Figure 14(b).

4. MEASUREMENTS

l=1 m Configuration

parallel

740 mm

L=2 m

1

VNA

Port 1 Antenna

Antenna 2

Port 2 1360 mm

(a) (b)

Figure 15. (a) Picture of the experimental setup in a wood box filled with 74 cm height sand coming from the Seine valley, and (b) geometry of the radar system in the parallel configuration that has been used for the FDTD simulations.

and length L = 2 m has been filled with a slightly humid and non-compacted sand coming from the Seine valley in France with a height of 74 cm. The measurements have been made using the vector network analyzer (VNA) ANRITSU MS4624B in the frequency band 50 MHz to 5 GHz. A full two ports calibration has been made with 3.5 mm radiofrequency coaxial cables. We have considered 1601 measurement points and a resolution bandwidth of 300 Hz. The antennas have been shielded using commercial planar five-layered absorbing materials. For practical reasons, the parallel configuration of the antenna system such as that presented in Figure 15(b) has first been studied. For the comparison between measurements and simulations, the numerical results involve a common soilε0

s= 5.5;σs= 0.01 S·m−1.

Firstly, considering an offset = 100 mm and an elevation h = 10 mm, we have compared the transmission between the pair of shielded antennas for three configurations: mirror, non-mirror, and parallel. The different frequency variations of S21 in Figure 16 show higher amplitudes at frequencies greater than 1 GHz for the non mirror configuration. TheS21amplitude of the mirror configuration decreases more regularly than the parallel configuration; the slope of the decrease appears similar.

Afterwards, considering the parallel configuration, we have compared measurement and simulation results for both coefficientsS11 and S21 in the frequency band from 0.1 to 4 GHz in Figures 17(a) and 17(b), respectively. In Figure 17(a), the peaks and hollows of the measurements agree satisfactorily with the simulations; the measurement variations versus frequency appear smoother. The S₁₁

-40

mirror

70 -60 -50

mirror non mirror parall el

-90 -80 -70

S

21

[d

B]

120 -110 -100

offset=100 mm

0 1 2 3 4

-120

frequency [GHz]

Figure 16. Theoretical transmission coefficient S21 (dB) versus frequency for three radar configurations in the presence of a common soil (ε0

s= 5.5; σs= 0.01 S·m−1, offset = 100 mm): mirror, non mirror

and parallel.

0 0

unshielded simulations

-40 -20 -10

bowtie antenna (shielded, plain lines) _measurements

offset=140 mm

offset 12 0 m m

-80 -60

S

11

[d

B]

-30 -20

S

11

[d

B]

E shaped measurements

(shielded)

simulations

offset=100 mm offset = 120 mm

120 -100 -80

50 -40

E-shaped antenna

simulations (unshielded, dot lines)

simulations

’=5.5; h=10 mm

’=4; h=10 mm ’=4; h=4 mm

0 0.5 1 1.5 2 2.5 3 3.5 4

-120

frequency [GHz]

0 0.5 1 1.5 2 2.5 3 3.5 4

-50

frequency [GHz]

(a) (b)

ε

ε

ε

Figure 17. Comparison between measurements and simulations in the presence of a homogeneous soil (ε0

s = 5.5; σs = 0.01 S·m−1).

(a) Return loss S11 (dB) considering a shielded and an unshielded rectangular slot antenna and an unshielded bowtie slot antenna, and (b) transmission coefficient S21 (dB) of the shielded rectangular slot antenna for different offsets in the parallel configuration.

0

-40

-20 measurements

(offset=7 cm)

80 -60 40

S21

[d

B]

-100 -80

simulations

(offset=7 cm, h=10 mm) simulations

(offset=7 h=4 mm )

0 1 2 3 4

-120

frequency [GHz] (offset=7 cm ,

Figure 18. Theoretical and experimental transmission coefficient

S21 (dB) of the shielded rectangular slot antenna in the non mirror configuration (ε0

s= 5.5;σs= 0.01 S·m−1).

operate at frequencies useful for GPR applications. The comparison between measurements and simulations for the transmission coefficient

S21 presented in Figure 17(b) show a marked amplitude difference (around 20 dB) at frequencies less than 1 GHz. This can be explained by the shielding of the antenna that was not complete during the measurements as no conductive box has been used for each antenna or by the curved shape of the cables connected to the VNA because of their short length. However, we remark from simulation results in Figure 17(b) that a soil with a lower permittivity ε0

s =

4(σs= 0.01 S·m−1), that a priori better corresponds to the sand

studied [16], significantly increases the S21 amplitude at frequencies higher than 0.8 GHz. Moreover, as during the experiments both antennas have been positioned at a weaker elevation than 10 mm, around 4 mm, we notice from the simulations that a lower height produces an increase in the S21 amplitude and particularly at frequencies higher than 0.6 MHz. Moreover, we remark that a weaker elevation induces a lower decreasing slope as a function of the frequency. Finally, S21 measurements have been made in the non mirror configuration for an offset around 7 cm. The measurements compared to simulation results (ε0_s = 4; σs = 0.01 S·m−1) with two

5. CONCLUSION

This paper has presented the simulation results associated with the broadband characteristics of an original rectangular slot antenna. The antenna is original as it has relatively short dimensions (34×29 cm2₎ to operate at a frequency as low as 0.27 GHz until 3.1 GHz. A low cross polarization in the E-plane in the overall frequency band characterizes this antenna. His gain is typical of microstrip antennas and could be improved. A detailed parametric study based on FDTD simulations has allowed to define its geometry which results from a suitable compromise on the feed line, the E-shaped patch, the tuning of the feed line, and the rectangular slot. The modeling of a radar system positioned close to the soil has been made in three different configurations to study in particular the coupling between both antennas through air and the soil. Afterwards, the presence of a buried object (pipe or crack all filled with air) has been considered to show the ability of the system to detect an object surrounded by a dielectric soil. Further studies will be focused on measurement campaigns in several environments (laboratory and controlled place) and the development of data processing to extract quantitative information from radar scans in different frequency sub-bands.

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